frc971/input/joystick_reader.cc - RealtimeRoboticsGroup/test - Gitiles

 #include <stdio.h>
 #include <string.h>
 #include <unistd.h>
 #include <math.h>

 #include "aos/linux_code/init.h"
 #include "aos/prime/input/joystick_input.h"
 #include "aos/common/logging/logging.h"

 #include "frc971/control_loops/drivetrain/drivetrain.q.h"
 #include "frc971/queues/gyro_angle.q.h"
 #include "frc971/autonomous/auto.q.h"

 using ::frc971::control_loops::drivetrain;
 using ::frc971::sensors::gyro;

 using ::aos::input::driver_station::ButtonLocation;
 using ::aos::input::driver_station::JoystickAxis;
 using ::aos::input::driver_station::ControlBit;

 namespace frc971 {
 namespace input {
 namespace joysticks {

 const ButtonLocation kDriveControlLoopEnable1(1, 7),
                      kDriveControlLoopEnable2(1, 11);
 const JoystickAxis kSteeringWheel(1, 1), kDriveThrottle(2, 2);
 const ButtonLocation kShiftHigh(2, 1), kShiftLow(2, 3);
 const ButtonLocation kQuickTurn(1, 5);

 class Reader : public ::aos::input::JoystickInput {
  public:
   Reader() {}

   virtual void RunIteration(const ::aos::input::driver_station::Data &data) {
     static bool is_high_gear = false;

     if (data.GetControlBit(ControlBit::kAutonomous)) {
       if (data.PosEdge(ControlBit::kEnabled)){
         LOG(INFO, "Starting auto mode\n");
         ::frc971::autonomous::autonomous.MakeWithBuilder()
             .run_auto(true).Send();
       } else if (data.NegEdge(ControlBit::kEnabled)) {
         LOG(INFO, "Stopping auto mode\n");
         ::frc971::autonomous::autonomous.MakeWithBuilder()
             .run_auto(false).Send();
       }
     } else {  // teleop
       bool is_control_loop_driving = false;
       double left_goal = 0.0;
       double right_goal = 0.0;
       const double wheel = -data.GetAxis(kSteeringWheel);
       const double throttle = -data.GetAxis(kDriveThrottle);
       LOG(DEBUG, "wheel %f throttle %f\n", wheel, throttle);
       const double kThrottleGain = 1.0 / 2.5;
       if (data.IsPressed(kDriveControlLoopEnable1) ||
           data.IsPressed(kDriveControlLoopEnable2)) {
         static double distance = 0.0;
         static double angle = 0.0;
         static double filtered_goal_distance = 0.0;
         if (data.PosEdge(kDriveControlLoopEnable1) ||
             data.PosEdge(kDriveControlLoopEnable2)) {
           if (drivetrain.position.FetchLatest() && gyro.FetchLatest()) {
             distance = (drivetrain.position->left_encoder +
                         drivetrain.position->right_encoder) / 2.0
                 - throttle * kThrottleGain / 2.0;
             angle = gyro->angle;
             filtered_goal_distance = distance;
           }
         }
         is_control_loop_driving = true;

         //const double gyro_angle = Gyro.View().angle;
         const double goal_theta = angle - wheel * 0.27;
         const double goal_distance = distance + throttle * kThrottleGain;
         const double robot_width = 22.0 / 100.0 * 2.54;
         const double kMaxVelocity = 0.6;
         if (goal_distance > kMaxVelocity * 0.02 + filtered_goal_distance) {
           filtered_goal_distance += kMaxVelocity * 0.02;
         } else if (goal_distance < -kMaxVelocity * 0.02 +
                    filtered_goal_distance) {
           filtered_goal_distance -= kMaxVelocity * 0.02;
         } else {
           filtered_goal_distance = goal_distance;
         }
         left_goal = filtered_goal_distance - robot_width * goal_theta / 2.0;
         right_goal = filtered_goal_distance + robot_width * goal_theta / 2.0;
         is_high_gear = false;

         LOG(DEBUG, "Left goal %f Right goal %f\n", left_goal, right_goal);
       }
       if (!(drivetrain.goal.MakeWithBuilder()
                 .steering(wheel)
                 .throttle(throttle)
                 .highgear(is_high_gear).quickturn(data.IsPressed(kQuickTurn))
                 .control_loop_driving(is_control_loop_driving)
                 .left_goal(left_goal).right_goal(right_goal).Send())) {
         LOG(WARNING, "sending stick values failed\n");
       }

       if (data.PosEdge(kShiftHigh)) {
         is_high_gear = false;
       }
       if (data.PosEdge(kShiftLow)) {
         is_high_gear = true;
       }
     }
   }
 };

 }  // namespace joysticks
 }  // namespace input
 }  // namespace frc971

 int main() {
   ::aos::Init();
   ::frc971::input::joysticks::Reader reader;
   reader.Run();
   ::aos::Cleanup();
 }
	#include <stdio.h>
	#include <string.h>
	#include <unistd.h>
	#include <math.h>

	#include "aos/linux_code/init.h"
	#include "aos/prime/input/joystick_input.h"
	#include "aos/common/logging/logging.h"

	#include "frc971/control_loops/drivetrain/drivetrain.q.h"
	#include "frc971/queues/gyro_angle.q.h"
	#include "frc971/autonomous/auto.q.h"

	using ::frc971::control_loops::drivetrain;
	using ::frc971::sensors::gyro;

	using ::aos::input::driver_station::ButtonLocation;
	using ::aos::input::driver_station::JoystickAxis;
	using ::aos::input::driver_station::ControlBit;

	namespace frc971 {
	namespace input {
	namespace joysticks {

	const ButtonLocation kDriveControlLoopEnable1(1, 7),
	kDriveControlLoopEnable2(1, 11);
	const JoystickAxis kSteeringWheel(1, 1), kDriveThrottle(2, 2);
	const ButtonLocation kShiftHigh(2, 1), kShiftLow(2, 3);
	const ButtonLocation kQuickTurn(1, 5);

	class Reader : public ::aos::input::JoystickInput {
	public:
	Reader() {}

	virtual void RunIteration(const ::aos::input::driver_station::Data &data) {
	static bool is_high_gear = false;

	if (data.GetControlBit(ControlBit::kAutonomous)) {
	if (data.PosEdge(ControlBit::kEnabled)){
	LOG(INFO, "Starting auto mode\n");
	::frc971::autonomous::autonomous.MakeWithBuilder()
	.run_auto(true).Send();
	} else if (data.NegEdge(ControlBit::kEnabled)) {
	LOG(INFO, "Stopping auto mode\n");
	::frc971::autonomous::autonomous.MakeWithBuilder()
	.run_auto(false).Send();
	}
	} else { // teleop
	bool is_control_loop_driving = false;
	double left_goal = 0.0;
	double right_goal = 0.0;
	const double wheel = -data.GetAxis(kSteeringWheel);
	const double throttle = -data.GetAxis(kDriveThrottle);
	LOG(DEBUG, "wheel %f throttle %f\n", wheel, throttle);
	const double kThrottleGain = 1.0 / 2.5;
	if (data.IsPressed(kDriveControlLoopEnable1) \|\|
	data.IsPressed(kDriveControlLoopEnable2)) {
	static double distance = 0.0;
	static double angle = 0.0;
	static double filtered_goal_distance = 0.0;
	if (data.PosEdge(kDriveControlLoopEnable1) \|\|
	data.PosEdge(kDriveControlLoopEnable2)) {
	if (drivetrain.position.FetchLatest() && gyro.FetchLatest()) {
	distance = (drivetrain.position->left_encoder +
	drivetrain.position->right_encoder) / 2.0
	- throttle * kThrottleGain / 2.0;
	angle = gyro->angle;
	filtered_goal_distance = distance;
	}
	}
	is_control_loop_driving = true;

	//const double gyro_angle = Gyro.View().angle;
	const double goal_theta = angle - wheel * 0.27;
	const double goal_distance = distance + throttle * kThrottleGain;
	const double robot_width = 22.0 / 100.0 * 2.54;
	const double kMaxVelocity = 0.6;
	if (goal_distance > kMaxVelocity * 0.02 + filtered_goal_distance) {
	filtered_goal_distance += kMaxVelocity * 0.02;
	} else if (goal_distance < -kMaxVelocity * 0.02 +
	filtered_goal_distance) {
	filtered_goal_distance -= kMaxVelocity * 0.02;
	} else {
	filtered_goal_distance = goal_distance;
	}
	left_goal = filtered_goal_distance - robot_width * goal_theta / 2.0;
	right_goal = filtered_goal_distance + robot_width * goal_theta / 2.0;
	is_high_gear = false;

	LOG(DEBUG, "Left goal %f Right goal %f\n", left_goal, right_goal);
	}
	if (!(drivetrain.goal.MakeWithBuilder()
	.steering(wheel)
	.throttle(throttle)
	.highgear(is_high_gear).quickturn(data.IsPressed(kQuickTurn))
	.control_loop_driving(is_control_loop_driving)
	.left_goal(left_goal).right_goal(right_goal).Send())) {
	LOG(WARNING, "sending stick values failed\n");
	}

	if (data.PosEdge(kShiftHigh)) {
	is_high_gear = false;
	}
	if (data.PosEdge(kShiftLow)) {
	is_high_gear = true;
	}
	}
	}
	};

	} // namespace joysticks
	} // namespace input
	} // namespace frc971

	int main() {
	::aos::Init();
	::frc971::input::joysticks::Reader reader;
	reader.Run();
	::aos::Cleanup();
	}